Energy Storage Science and Technology ›› 2024, Vol. 13 ›› Issue (3): 788-824.doi: 10.19799/j.cnki.2095-4239.2023.0826
• Energy Storage Materials and Devices • Previous Articles Next Articles
Chenxi LIANG1(
), Zhenbin WANG1,2, Mingjin ZHANG1,2(), Cunhua MA1,2(), Ning LIANG3,4
Received:2023-11-16
Revised:2023-12-07
Online:2024-03-28
Published:2024-03-28
Contact:
Mingjin ZHANG, Cunhua MA
E-mail:1658548263@qq.com;zhangmingjin@qhnu.edu.cn;20211001@qhnu.edu.cn
CLC Number:
Chenxi LIANG, Zhenbin WANG, Mingjin ZHANG, Cunhua MA, Ning LIANG. Research progress on magnesium-based solid hydrogen storage nanomaterials[J]. Energy Storage Science and Technology, 2024, 13(3): 788-824.
Table 1
Comparison of gas, liquid and solid hydrogen storage methods"
| 储氢类型 | 气态储氢 | 液态储氢 | 固态储氢 |
|---|---|---|---|
| 储氢原理 | 通过压缩、吸附等方式将氢气储存于钢瓶中 | 将氢气冷却到20 K,进行液化储存 | 使用固体材料,通过物理或化学吸附实现吸氢 |
储氢密度 (质量分数) | 1%~5%(含气瓶) | 5.5%(含储罐) | 1.4%~20% |
| 优点 | 1. 吸放氢速度快 2. 能在零下几十度环境下工作 | 1. 液态氢密度高 2. 储氢量大 | 1. 储氢量大 2. 不易爆炸,安全性好 3. 储存、运输方便 4. 多数材料可循环使用 |
| 缺点 | 1. 易泄漏,危险系数高 2. 储氢量低 | 1. 液化过程氢的热值损耗20%~30% 2. 需要苛刻的绝热条件 | 1. 储氢量与吸放氢温度不能兼顾 2. 多数材料使用前需要进行循环活化 |
Fig.1
Common crystal structures of magnesium hydride [33]"
Fig.2
The corresponding P-T phase diagram of MgH2 [33]"
Fig. 3
(a)Pressure component isotherm diagram of Mg/MgH2 and (b)Van′ t Hoff diagram corresponding to the Mg/MgH2 phase transition[38]"
Fig.4
The hydrogen absorption content obtained from the PC isotherms of different Mg-Ni system alloys at 373 K[51]"
Fig.5
DSC curves of Mg100-x Ni x (x=0, 5, 10 and 20) alloys after HCS+MM[52]"
Fig.6
(a) DSC and (b) TPD curves of Mg80Ni20H x before and after exposure for 15 days, 4 and 10 months, isothermal (c) hydrogenation and (d) dehydrogenation curves of Mg80Ni20H x before and after air exposure for 4 months, (e) JMAK fitting plots and (f) Arrhenius plot of air-exposed Mg80Ni20H x for the dehydriding kinetics [53]"
Table 2
Hydrogen storage capacity and dehydrogenation enthalpy of some binary magnesium alloys"
| 合金 | 脱氢焓ΔH/(kJ/mol) | 储氢量(质量分数)/% | 文献 |
|---|---|---|---|
| MgAl | 62.7 | 4.44 | [ |
| Mg2Fe | 87.0 | 5.5 | [ |
| Mg2Si | 36.4 | 5.0 | [ |
| Mg0.95In0.05 | 68.1 | 5.3 | [ |
| Mg3La | 81.0 | 2.89 | [ |
Fig. 7
Hydrogenation and dehydrogenation curves of the Mg-Al and Mg-Al-TM(TM=Ti、Ni、V)alloys[60]"
Fig. 8
Arrhenius plots of the Mg95-x Al5Y x (x=0~5)[61]: (a)Y0 alloys; (b)Y1 alloys; (c)Y2 alloys; (d)Y3 alloys; (e)Y4 alloys and (f)Y5 alloys"
Fig. 9
Isothermal hydrogen absorption curves of the activated Mg95-x Ni x Y5(x=5, 10, 15)samples in different temperatures: (a)Mg90Ni5Y5; (b)Mg85Ni10Y5; (c)Mg80Ni15Y5 and (d)the comparison of hydrogen absorption rate of these samples at optimum hydrogenated temperature [63]"
Fig. 10
200-cycle dehydrogenation performance diagram of Mg91Ni9 and Mg91Ni8La1 [65]"
Table 3
Corresponding hydrogen storage parameters of some magnesium alloys"
| 合金 | 脱氢活化能Ea/(kJ/mol) | 初始脱氢温度T/℃ | 脱氢焓ΔH/(kJ/mol) | 脱氢量/%(质量分数) | 文献 |
|---|---|---|---|---|---|
| Gd5Mg80Ni15 | 75.07 | 280 | 75.1 | 4.87 | [ |
| Mg90Ce3Ni7 | 72.2 | 100 | 80.0 | 3.5 | [ |
| Mg98Ni1.67La0.33 | 107.26 | 175 | — | 5.59 | [ |
| Mg90Ce5Sm5 | 106 | 300 | 81.2 | 4.95 | [ |
| Mg96Y2Zn2 | 166.504 | 389 | — | 6.2 | [ |
| Mg80Ni10La64 | 70.30 | 278.4 | — | 4.7 | [ |
| Mg22Y3Ni9C | 66.13 | 235.1 | 64.29 | 2.8 | [ |
| AlMg2TiZn | 148 | 310 | 76 | 1.4 | [ |
Fig.11
Hydrogen absorption curves of Mg x TiVNiAlCr(x=0, 0.5, 1)at 473 K, 523 K, 573 K [75]"
Fig. 12
Comparison between the variation of the reversible hydrogen storage capacity during cycling for the quinary Mg0.1Ti0.3V0.25Zr0.1Nb0.25 and quaternary Ti0.325V0.275Zr0.125Nb0.275 alloys [76]"
Fig. 13
Schematic of the catalytic mechanism and cycle properties of the nano-MgH2-Ni system [87]"
Fig. 14
Diagram of the catalytic mechanism of MgC0.5Co3[89]"
Fig. 15
Diagram of the mechanism of hydrogen storage under air exposure of Mg NCs/PMMA [95]"
Fig. 16
TEM micrographs for the cross section of (a) Pd (25 nm)/Mg (200 nm) and (b) Pd (50 nm)/Mg (200 nm)/Pd (50 nm) films [101]"
Fig. 17
Hydrogen absorption of Mg-PMMA nanocomposites containing 33.2%, 49%, 54.7%, 58.2% and 65% Mg [106]"
Fig. 18
Preparation process, catalytic phase characterization, and cycling performance diagram of MgH2@CoS-NBs [109]"
Table 4
Performance differences and technical difficulties of MgH2 prepared by different methods"
| 材料 | 制备方法 | 尺寸/nm | 脱氢量 /%(质量分数) | 脱氢Ea/(kJ/mol) | 技术难点 | 文献 |
|---|---|---|---|---|---|---|
| MgH2 | 高能球磨 | — | 7 | — | 球磨时间过长,效率较低 | [ |
| MgH2 | 介质阻挡放电等离子体辅助球磨 | 2~6 | 6.5 | — | 设备要求过高 | [ |
| MgH2-MgC0.5Co3 | 氢化燃烧合成法 | — | 4.38 | 126.7±1.4 | 制备过程存在危险性 | [ |
| 胶体MgH2 | 化学还原法 | 5 | 7.6 | — | 材料的规模和形貌难以调控 | [ |
| Mg纳米线 | 气相沉积法 | 30~170 | 7.6 | — | 制备过程复杂 | [ |
| MgH2@Ni-MOF | 纳米限域 | 3 | 1.45 | 41.5±3.7 | 材料储氢性能较差 | [ |
Fig. 19
TEM image of the Mg-Ti nanopowder [114]"
Fig. 20
TGA profiles of the hydrogenated products of the Mg-Ti nanopowder(A)MgH2-5%Ti(CVS); (B)commerical MgH2; (C)MgH2-5%Ti(milled)[114]"
Fig. 21
Thermal desorption mass spectra of hydrogen from the MgH2 composite with 1?mol% Ni by milling for 15?min, 1?h, and 2?h at 400?r/min under a hydrogen gas atmosphere of 1?MPa [115]"
Fig. 22
Hydrogen desorption curves of the (a) MgH2 milled for 2 h; (b) MgH2+10%Ni; (c) MgH2+25% Ni; (d) MgH2+50% Ni, and (e) MgH2+80% Ni at 523 K under an initial pressure of 0.01bar of H2[116]"
Fig. 23
Comparison of the effects of different Ni particle sizes on the desorption properties of pre-milled MgH2 by simply mixed 20 h-pre-milled MgH2 and different types Ni (90 nm, 100 nm, 200 nm and 7 μm)[117]"
Fig. 24
The adsorption geometry of MgH2 on Fe (110)surface in top view (a); The brown, green, and white ball represent Fe, Mg, and H, respectively, The projected density of states (PDOS)of Mg and H of MgH2 before (upper)and after (lower)adsorption on Fe (110)surface (b) [108]"
Fig. 25
Schematic diagram of the hydrogenation and dehydrogenation mechanisms of MgH2/TiO2 heterostructure[127]"
Fig. 26
(a)Temperature-programmed-desorption and (b) isothermal dehydrogenation curves at 275 ℃ of MgH2, MgH2-5%Ni/Al2O3 and MgH2-5%NiO/Al2O3 ; isothermal dehydrogenation curves of (c)MgH2-5%NiO/Al2O3 and (d)MgH2-5%Ni/Al2O3 at different temperatures of 250 ℃, 275 ℃ and 300 ℃; (e)the corresponding solid-state reaction mechanism model and rate-controlling step of MgH2-5%Ni/Al2O3; (f)time dependence of the kinetic modeling equation F(α)and the plot for the temperature-dependent rate constant k, obtained by the Arrhenius equation[128]"
Fig. 27
Schematic diagram of the microstructural evolution for the MgH2@5%Sc2O3/TiO2 composite during the hydrogenation-dehydrogenation process [130]"
Fig. 28
XRD patterns of MgH2+7% LiCoO2 composite: after ball milling, after dehydrogenation and after rehydrogenation [131]"
Fig. 29
(a)Isothermal dehydrogenation curves of MgH2-6 wt% MnCo2O4.5 and (c)as-milled MgH2; (b)isothermal hydrogenation curves of MgH2-6 wt% MnCo2O4.5 and (d)as-milled MgH2; (e)de/hydrogenation cycle curves of MgH2-6 wt% MnCo2O4.5 at 325 ℃, and (f)decay curves of hydrogen storage capacity[120]"
Table 5
Hydrogen storage properties of some MgH2- ternary transition metal oxides"
| 材料 | 初始脱氢T/℃ | 脱氢Ea/ (kJ/mol) | 脱氢量/%(质量分数) | 文献 |
|---|---|---|---|---|
| MgH2-BiVO4 | 265 | 84.33 | 1.1 | [ |
| MgH2-TiNb2O7 | 178 | 100.4±0.1 | 7.0 | [ |
| MgH2-MnV2O6 | 182.1 | 67±0.7 | 5.57 | [ |
| MgH2-NiTiO3 | 235 | 74±4 | 7.1 | [ |
| MgH2-TiVO3.5 | 197 | 62.4 | 5.0 | [ |
| MgH2-NiV2O6 | 227 | 75.32±4.2 | 5.3 | [ |
| MgH2-LiNbO3 | 228 | 79.2±0.5 | 5.45 | [ |
| MgH2-NaNbO3 | 251 | 73 | 6.5 | [ |
Fig. 30
XRD patterns of MgH2+5%K2NiF6 composite: after ball milling, after dehydrogenation and after rehydrogenation [144]"
Fig. 31
Schematic illustration of the catalytic mechanism of the K2TaF7-catalyzed MgH2 composite[145]"
Fig. 32
Schematic diagram of the hydrogenation/dehydrogenation processes of the MgH2-FeNi2S4 composite [147]"
Fig. 33
Isothermal hydriding curves of the Mg, Mg/ZIF-8, Mg/ZIF-67, and Mg/MOF-74composites [154]: (a)hydrogenation process at 175 ℃; (b)dehydrogenation process at 300 ℃"
Fig. 34
(a)Typical bright field TEM micrograph; (b)the corresponding SAED pattern; (c)、(d)the HRTEM images, (e)—(i)the dark field micrographs and the corresponding elemental mappings of MgH2-5% Ni-MOF after 11th hydrogenation[155]"
Fig. 35
Isothermal hydrogenation/dehydrogenation curves of MgNb and MgNb/ZIF-67 nanocomposites at (a)175 ℃ and (b)275 ℃ [156]"
Fig. 36
(a)、(b) SEM micrographs of the Mg and MgNb/ZIF-67 nanocomposites (c)—(e)TEM images and SAED of MgNb/ZIF-67 after 100 hydrogen absorption/desorption cycles[156]"
Fig. 37
The mechanism diagram and corresponding dehydrogenation curve of MgH2 improved by Nb2O5 and MOF [157]"
Table 6
Summary of hydrogen storage properties of MgH2 modified by some other metal compounds"
| 材料 | 初始脱氢T/℃ | 脱氢Ea/ (kJ/mol) | 脱氢量/%(质量分数) | 文献 |
|---|---|---|---|---|
| Mg-NiF2 | 362 | 139.21 | 3.85 | [ |
| MgH2-K2NiF6 | 260 | 111.0 | 4.9 | [ |
| MgH2-TiS2 | 204 | 50.8 | 5.9 | [ |
MgH2-FeNi2S4 Mg/ZIF-67 MgH2-Ni-MOF MgH2-Nb2O5@MOF | 267 275 292 181.9 | 65.5 161.73 107.8 75.57±4.16 | 1.92 3.7 5.7 6.2 | [ [ [ [ |
Fig. 38
Schematic illustration for the “bidirectional catalysis” mechanism of Co/Pd@B-CNTs on the dehydrogenation and hydrogenation of MgH2[164]"
Fig. 39
Schematic diagram of the catalytic mechanism of catalysts during the hydrogenation/dehydrogenation processes of the MgH2-5 wt%Ni3ZnC0.7/Ni@CNT nanocomposite[165]"
Fig. 40
The corresponding lnk vs 1000/T plots for hydrogenated (a) and dehydrogenated (b) MgH2-xNZC/Ni@CNT (x=2.5%, 5%, 7.5%)composites. Comparison of TPD curves (c) of MgH2-xNZC/Ni@CNT (x=2.5%, 5%, 7.5%)and MgH2[165]"
Fig. 41
(a) enthalpy change of graphene-doped Mg4H8 dehydrogenation and (b) activation energy of MgH2 [166]"
Fig. 42
Adsorption dehydrogenation curves of MgH2 and MgH2+10%Fe-Ni@3DG: (a) isothermal hydrogen absorption; (b) isothermal dehydrogenation; (c) cyclic performance diagram of MgH2; (d) cyclic performance diagram of MgH2+10%Fe-Ni@3DG[167]"
Fig. 43
(a) Isothermal hydrogenation curves of commercial MgH2, hyd-MgBu2, and 60% MgH2@Ti-MX at 175 ℃ and (b) isothermal hydrogenation curves of 60% MgH2@Ti-MX at different temperatures; (c) cycling dehydrogenation curves of 60% MgH2@Ti-MX at 200 ℃, and (d) typical TEM image of 60% MgH2@Ti-MX after 60 de/hydrogenation cycles at 200 ℃[173]"
Fig. 44
(a) Schematic pictures showing the hydrogen desorption and absorption mechanisms of MgH2 with addition of V2C/Ti3C2 and (b) schematic diagram comparatively displaying the energy barriers for as-milled MgH2 and MgH2-V2C/Ti3C2[174]"
Table 7
Hydrogen storage performance of MgH2 modified by some metal and carbon based composite catalysts"
| 材料 | 脱氢Ea/(kJ/mol) | 初始脱氢T/℃ | 脱氢ΔH/(kJ/mol) | 脱氢量/%(质量分数) | 文献 |
|---|---|---|---|---|---|
MgH2-Co/Pd@BCNTs MgH2-Ni3ZnC0.7/CNT MgH2+Fe–Ni@3DG MgH2- CoNi@C | 76.66 84.22 83.8 78.5 | 198.9 110 — 173 | — 75.17 72.2 — | 6.35 5.36 5.13 5.83 | [ [ [ [ |
| MgH2-ML-Ti3C2 | 99 | 142 | — | 6.45 | [ |
| MgH2-NbTiC | 80 | 195 | — | 5.8 | [ |
| MgH2-PrF3/Ti3C2 | 78.11 | 180 | — | 7.0 | [ |
| MgH2-V2C | 87.6 | 190 | 73.6 | 6.4 | [ |
Fig. 45
Comparison of MgH2-5%FeCoNiCrMn and milled MgH2[180]: (a) TPD curves; (b) dehydrogenation content when heated to different temperatures; (c)、(e) isothermal dehydrogenation curves; (d)、(f) isothermal hydrogenation curves"
Fig. 46
Schematic representation of catalytic mechanism of catalyst (LHEA) during dehydrogenation of MgH2 [181]"
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